A review on high‐temperature thermochemical heat storage: Particle reactors and materials based on solid–gas reactions

IF 5.4 3区 工程技术 Q2 ENERGY & FUELS
Selvan Bellan, T. Kodama, N. Gokon, K. Matsubara
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引用次数: 7

Abstract

In order to produce electricity beyond insolation hours and supply to the electrical grid, thermal energy storage (TES) system plays a major role in CSP (concentrated solar power) plants. Current CSP plants use molten salts as both sensible heat storage media and heat transfer fluid, to operate up to 560°C. To meet the future high operating temperature and efficiency, thermochemical storage (TCS) emerged as an attractive alternatives for next generation CSP plants. In these systems, the solar thermal energy is stored by endothermic reaction and subsequently released when the energy is needed by exothermic reversible reaction. This review compares and summarizes different thermochemical storage systems that are currently being investigated, especially TCS based on metal oxides. Various experimental, numerical, and technological studies on the development of particle reactors and materials for high‐temperature TCS applications are presented. Advantages and disadvantages of different types heat storage systems (sensible, latent, and thermochemical), and particle receivers (stacked, fluidized, and entrained), have been discussed and reported.

Abstract Image

高温热化学储热综述:基于固体-气体反应的粒子反应器和材料
为了在日照时间之外发电并向电网供电,热能储存(TES)系统在聚光太阳能(CSP)发电厂中起着重要作用。目前的CSP电站使用熔盐作为显热储存介质和传热流体,运行温度可达560°C。为了满足未来的高工作温度和高效率,热化学储存(TCS)成为下一代CSP电厂的一个有吸引力的替代方案。在这些系统中,太阳热能通过吸热反应储存,当需要放热可逆反应时释放出来。本文对目前正在研究的热化学存储系统进行了比较和总结,特别是基于金属氧化物的热化学存储系统。介绍了用于高温TCS应用的颗粒反应器和材料的各种实验、数值和技术研究。不同类型的蓄热系统(感热、潜热和热化学)和颗粒接收器(堆积式、流化式和夹带式)的优缺点已经被讨论和报道。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
11.70
自引率
3.30%
发文量
42
期刊介绍: Wiley Interdisciplinary Reviews: Energy and Environmentis a new type of review journal covering all aspects of energy technology, security and environmental impact. Energy is one of the most critical resources for the welfare and prosperity of society. It also causes adverse environmental and societal effects, notably climate change which is the severest global problem in the modern age. Finding satisfactory solutions to the challenges ahead will need a linking of energy technology innovations, security, energy poverty, and environmental and climate impacts. The broad scope of energy issues demands collaboration between different disciplines of science and technology, and strong interaction between engineering, physical and life scientists, economists, sociologists and policy-makers.
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